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Bridging the Twenty-First Century Gap in Education – History, Causation, and Solutions

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Bridging the Twenty-First Century Gap in Education – History, Causation, and Solutions Part 1 Educational Transitions in Context Downloaded from https://www.cambridge.org/core. IP address: 170.106.35.229, on 27 Sep 2021 at 15:19:29, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms. https://doi.org/10.1017/S1062798720000873 European Review, Vol. 28, No. S1, S7–S27 © 2020 Academia Europaea. This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/ licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited. doi:10.1017/S1062798720000873 Cognitive Context Bridging the Twenty-first Century Gap in Education – History, Causation, and Solutions ANDREAS DEMETRIOU Cyprus Academy of Science, Letters, and Arts, Faneromenis 60-68, 1010 Nicosia, Cyprus. Email: [email protected] This article discusses the gaps in the cognitive demands of education as higher levels of education became socially and culturally necessary. These gaps are related to major transitions between education levels, such as the transition from preschool to primary school, from primary to secondary, or from secondary to tertiary educa- tion. Gaps reflect deviations between the concepts and skills prescribed for learning by a specific population and the readiness of this population to cope with the demands of the task within the time frame prescribed. The history and the cognitive developmental profile of the gaps is outlined. This article focuses on the gap between secondary and tertiary education. It is explained that a major reason for the gap is the vast expansion in the population of youth attending university studies. We out- line a programme for bridging this gap, which extends from primary to university education. We emphasize changes in principle-based and critical thought that are needed by many students if they are be able to grasp science as intended by universities. A gap requires two distant sides to exist. In education, students and instruction are the two sides of the gap. A gap between them implies that students cannot cope with the new learning demands when moving from one level of education to the next. These gaps are related to major transitions between education levels, such as the transition from preschool to primary school, from primary to secondary, or from secondary to tertiary education. Gaps reflect deviations between the concepts and skills prescribed for learning by a specific population (e.g. reading and writing in early primary school, algebra in early secondary school, scientific theories at college) and the readiness of this population to cope with the demands of the task within the time frame prescribed. For instance, at transition from preschool to primary school, Downloaded from https://www.cambridge.org/core. IP address: 170.106.35.229, on 27 Sep 2021 at 15:19:29, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms. https://doi.org/10.1017/S1062798720000873 S8 Andreas Demetriou ideally all children must be ready to acquire the skills needed to learn to read and write at first grade; at transition from primary to secondary school, ideally all children must be ready to learn basic algebra or science concepts. This requires that children are prepared by the previous level of education, preschool in the first and primary school in the second example above, to cope with the learning tasks of the new level. For instance, in reading, to focus on visual patterns, connect them to pho- nological patterns, and integrate them into words; in algebra, to generalize numbers into abstract dimensions and operate on their logical relations. A gap would exist between two levels, if the new learning tasks are impossible for a large number of children. Obviously, gaps may appear in any school year for individual students for various reasons, such as specific delays in their intellectual development relative to a school subject, teachers’ failures to meet specific needs of individual students, etc. However, these gaps are treated as individual learning difficulties rather than gaps between educational levels. This paper focuses on gaps between educational levels rather than gaps in individual learning and development. The meeting of Academia Europaea (the European Academy of Sciences and Humanities) on bridging the gap between secondary and tertiary education reflects a problem of concern in our universities: many students admitted to universities are not ready to grasp science as required. This gap has several serious implications. For instance, it may compromise the quality of education and professional skills pro- vided by universities. Alternatively, it may cause students to change programmes of study or to drop out altogether, disturbing universities, personal or family lives, or various aspects of the economy or production (SUnStAR 2019). I shall argue here that this problem is not unique for our time. It is a signal of a major change in the knowledge and cognitive skills required by society at its current stage of develop- ment. It happened in the past when similar changes occurred. Below, I shall first place the problem in an epistemological and historical perspective. Then I shall analyse the problem from the perspective of cognitive and developmental science and propose ideas for its solution. Table 1 summarizes the three major educational gaps discussed in the paper, the solutions implemented so far, the residuals problems remaining after bridging the three gaps, and the skills still lacking from explicit educational goals and programmes. Cultures of Knowledge and Science Three cultures of knowledge thrive in the modern university: natural sciences, social sciences, and humanities (Kagan 2009). There are commonalities and differences between these cultures. They are all supposed to be driven by truth in their attempt to describe and understand the world and motivate improvement of human life. They all involve a long history of scholarship which generates complex and demanding systems of knowledge and related professional activity. Mastering a discipline in each of them requires learning a body of knowledge which is often highly abstract and very distant from observable reality. One might mention here relativity in phys- ics, DNA in biology, general intelligence in psychology, deep structure in linguistics, Downloaded from https://www.cambridge.org/core. IP address: 170.106.35.229, on 27 Sep 2021 at 15:19:29, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms. https://doi.org/10.1017/S1062798720000873 https://www.cambridge.org/core/terms Downloaded from https://www.cambridge.org/core Table 1. Summary of education gaps and solutions implemented. Solutions implemented . https://doi.org/10.1017/S1062798720000873 Educational Gaps Learning tasks (or needed) Residual problems Skills not explicitly taught From no to Reading, writing, arithmetic, Compulsory preschool- Specific learning Teaching of executive control . IPaddress: primary basic concepts and skills of education, learning science- difficulties, e.g. processes, such as attention education learning and functioning in based programmes for dyslexia, dyscalculia, control and representational the society, general science teaching reading, writing, behavioural problems awareness. concepts related to actual life arithmetic and other concepts at school. 170.106.35.229 and experience, basic and basic study habits. problem-solving skills. From primary Reading and understanding of Compulsory junior secondary Literacy and numeracy Systematic rule-based thought , on to secondary complex texts, self-guided education, new learning difficulties, failure to and its main underlying education learning and knowledge science-based curricula. grasp basic science reasoning tools. Grasp of 27 Sep2021 at15:19:29 acquisition, grasp of abstract concepts, low principle-based reasoning. concepts from different adaptability in Awareness of inference as a disciplines, problem-solving unfamiliar problem-solving tool. of new/unfamiliar problems. environments. From secondary Grasp of scientific theories, University-oriented curricula Failure to understand Differences between cultures of to tertiary models, and methods, in various subjects. science as a systematic knowledge (i.e. natural, social Cognitive Context , subjectto theCambridgeCore termsofuse,available at education mastering of high-level self-correcting approach science and humanities) in professional skills required for to understanding and concepts and methods. professional problem-solving changing the world. Critical/epistemic reasoning. associated with one’s Logical awareness, accurate discipline. self-evaluation in different domains. S9 S10 Andreas Demetriou Keynesian theory in economics, literary theory in literature, etc. It also requires learning methods and codes of operation ruling how theories may be evaluated, combined, improved or rejected. In their professional applications, they involve knowledge and rules underlying problem-solving in related professions, such as the relations between the natural sciences and engineering, biology and clinical prac- tice in medicine, theories of learning and education, etc. These three cultures differ drastically, despite their similarities. The natural and social sciences are taxonomic, causal, explanatory, and predictive. Their primary aim is to model causal relations between variables and allow predictions
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